CN101688875B - Method for measuring amount of analyte in bilfluid in microfluidic device - Google Patents

Abstract

An assay wherein a biological fluid sample is dispensed into an inlet of a microfluidic device by dispensing said biological sample and/or associated liquid in droplets and at intervals in order to control the operation of said microfluidic device, The accuracy and reproducibility of the assay is improved.

Description

In microfluidic device, measure the method for the amount of analyte in biofluid

Technical field

The present invention relates to for measuring reagent and the instrument of biological sample analyte quantity, it is realized to produce detectable response by described analyte and reagent reacting.

background technology

Containing dispense liquid on the base material of reagent

Developed many instruments and measured the quantity of analyte in biological sample, described biological sample is for example urine, blood, saliva or mucus or tissue extract.Conventionally, sample liquids is applied on the surface of containing with the reagent of described analyte response.Described reagent produces detectable response, measures this response and it is associated with the amount of described analyte.In described surface nature, be generally hydrophilic or hydrophobic, for example filter paper in contrast to polystyrene.Some devices have adopted the combination on a plurality of surfaces, for example urinalysis bar test, and it has used hydrophilic filter paper pads on hydrophobic polystyrene handle top.In typical test, the bar that contains unreacting reagent is dipped, immerse completely in fluid sample, then measure reacting between analyte and reagent in described sample, described measurement normally realizes by optical means.Described unreacted reagent itself can be water-soluble or non-water-soluble.They deposit or fix and be dried in porous substrate.Described base material connects or is placed on load-bearing surface.In addition, can in mensuration process, use the liquid that contains or do not contain reagent.Described liquid reagent can with before the reacting of analyte, afterwards or in process, be applied on the substrate surface that has contained dried reagent, normally after sample applies, add.Obviously, for the purpose of the reason of cost and convenience etc., the volume of sample and reagent should be as much as possible little.Less obvious, when applying a small amount of liquid reagent or biological sample on the surface of containing reagent time, be conventionally difficult to obtain evenly and accurately response.When there is little and a small amount of analyte, analyte is less than described conversion zone with reacting of reagent.

Described base material can be used to amplify the response of described reaction.Film, for example film, can fix so that reactant catching and concentrating in read area with compatibility reagent.For example, at desirable direction (horizontal but not longitudinal) guiding liquids, flow and can raise the efficiency owing to having increased the quantity of fluid communication between fluid sample or reagent and reaction zone.Each exchange makes analyte that further reaction occur, thereby has amplified described signal.The modification of described substrate surface makes the reagent can be separated in reaction zone.In addition, the character on described surface itself also can be used for improving the reactivity of analyte, for example by increase the dissolubility of reagent or promote on described surface with reagent react realize.

Therefore most of biological samples and liquid reagent have significant liquid water content, are compatible to hydrophilic base and are not dissolved in hydrophobic surface.When described sample and reagent liquid distribute, can be dispersed in fast on hydrophilic base and repelled by hydrophobic substrates.On described surface, contacting by being directly assigned on conversion zone or partial reaction region between dispense liquid and reagent realized.Yet when base material is relatively hydrophobic, the liquid distributing can form liquid pearl to attempt to minimize itself and the contacting of described surface on described substrate surface, thus its can uniformly dispersing on described reagent.Another difficult problem relevant with dispense liquid is that dried reagent may be water miscible or non-water-soluble in nature.Non-water-soluble dried reagent may be not easy to be reached by described fluid sample, and water miscible reagent may dissolve and move on described base material with liquid.It is desirable to described reagent should uniform contact sample, because measurable response of described reagent and sample, for example colour developing, should be evenly to obtain the accurate reading of analyte quantity in described sample.

Liquid another problem relevant with the good contact between reagent being assigned with from the teeth outwards with acquisition relates to the physical property of described sample.Its physical property as surface tension, viscosity, total solids content, grain size and adhesion be to change to some extent.Therefore, it is not easy to be deposited on equably on the base material being covered by reagent with consistent volume.Equally, along with the minimizing of fluid sample amount, the sample with qualitative change of unanimously measuring is applied on reagent and becomes more and more difficult.On the contrary, inkjet printing etc. just depends on as this purposes liquid that develop and that have consistent physical property.

The deposition of drop is common operation.Example comprises ink-jet printer, piezoelectricity or bubble activate, described in the black printer of disputing by comprising several ascending to heaven (femtoliter), to tens controlled depositions of a plurality of droplets of receiving about 2 to the 300 μ m of diameter (being generally 50 μ m) that rise, form trace.Other method that has proposed deposition droplet, although it is different with typical ink-jet printer, adopts piezoelectric principle to form drop conventionally.The example sees US Patent No. 5063396,5518179, in 6394363 and 6656432.By larger known can the reproduction in diagnostic system of drop (3-100 μ L) of injector type transfer pipet deposition.This is corresponding to approximately 2 to 6mm single liquid-drop diameter.The commercial examples of this pipette systems is CLINITEK urine examination analyser.Droplet size can be for being greater than or less than the size of nozzle, and this depends on the shape of nozzle, the type of pump and institute's applied pressure.

When fluid sample is assigned on the pad that comprises reagent with the form of drop, observed especially problem discussed above.It is found that, when sample with the form of drop, add rather than as common way by by reagent pad immersion (dipping) when covering described reagent pad completely in sample liquids, surface and the interaction between reagent of described pad can form inaccurate response.When the hydrophobicity of base material is crossed when strong, the large drop of 3 to the 100 μ L orders of magnitude can not transferred in reagent but form from the teeth outwards bubble.If surface is hydrophilic, its (overwhelm) described reagent that can be annihilated with too much fluid again.Several ascending to heaven to tens received also can having problems when being deposited over the base material that hydrophobicity is excessively strong on time compared with droplet of rising, and this is not have because of it volume that covers described surface area completely, and can be with inhomogeneous pattern random aggregation.Droplet has also allowed to make the open space of water-soluble reagent migration.These fine droplets also tend to occur liquid evaporation and form gasoloid, and this is considered to have biohazardous, if described gasoloid comprises urine or blood sample.Therefore,, if liquid is deposited in testing cushion rather than by pad and is immersed in sample with the form of drop, need to improve.

After contacting completely between distributed liquid and reagent, can adopt a kind of in several different methods to carry out reading result.Conventionally adopt optical means, it depends on spectral signal to produce response.In order to become useful consequence, result must be reproducible.Optical measurement is subject to the impact of the time that the impact of observed reagent areas and the dispensable liquid allowing and reagent react.In the visual field, the variation of the formation of non-uniform areas and reaction time amount can increase error.For example, to crossing unevenly the measurement that sample that base material scatters or reagent carries out, when reading, can provide different results at every turn.

In the common unsettled U.S. Patent application 11/135928 of announcing as U.S.2006/0263902A1, inventor reported its with fine droplet form sedimentary organism fluid and reagent to the method being loaded with on the base material of reagent, described application and the application are transferred jointly.The base material that their proof is loaded with reagent depends on that the surface of the water-soluble and described base material of described reagent can (that is the base material that, is loaded with reagent described in depending on be hydrophilic or hydrophobic) and performance difference.When depositing the droplet of about 50pL to 1 μ L on being loaded with the surface of reagent, deposit large drop, for example 1.7-20.4 μ L, shows and has more inaccurate result.Inventor also finds that droplet is absorbed by described hydrophobic substrates, and large drop is not easy to be absorbed.

While scattering on the surface that is being loaded with reagent, water-soluble reagent shows dissolved and moves together with liquid.Inventor's discovery, the inhomogeneous reagent response that this movement causes can relax by deposition droplet.

Deposition droplet can be by having the nozzle of many little openings or realizing by single-nozzle, and described nozzle can move relative to the base material that is loaded with reagent, or vice versa, to cover predetermined region.Fluid sample reacts the mean value that can pronounce as sample overlay area with reagent on described base material, or preferably by scanning conversion zone more once, gets the mean value of result again.

To deposit liquid in microfluidic device

To the microfluidic device for biological sample analysis, add biological sample and relevant liquid can be realized by various technology.The samples such as very small amount of blood, urine are introduced to this device, therein they with can indicate in described sample analyte to exist and the reagent of quantity comes in contact.

In the U.S. Patent application US 10/608671 announcing as U.S.2004/0265172A1, discussed and sedimentary organism sample and may be for analyzing the problem that other required liquid of described sample is relevant.Particularly important needs have when liquid is introduced removes air from described device, and metering is added described analyzed sample and related fluid style as the amount of reagent, damping fluid, dilution etc.

Even if having been found that the amount of measuring analyte in biological sample may can not have the needed repeatability of people yet after the microfluidic device design by suitable has overcome the problem just now discussed.This problem partly cause relates to intrinsic changeability in these designs.First, the changeability in surface coating can cause liquid spread cross capillary barrier or be positioned at around reagent areas.This has caused timing that liquid moves and the variation of reaction volume.Secondly, the less user of experience can apply sample or the reagent of incorrect amount.The 3rd, when producing in a large number with cost effective method, the inside dimension of these microfluidic devices can be complied with each chip and difference.Inventor's discovery, these problems can be overcome, and the accuracy of result and repeatability are significantly improved.

Innovation and creation content

One aspect of the present invention relates to for being determined at improving one's methods of amount of analyte that biofluid comprises.Described method comprises that the form at the drop of 0.05 to 1mm scope is assigned to biologicfluid sample and/or relevant liquid in the entrance of microfluidic device with diameter.Minute being equipped with predetermined number of times (times) and carrying out of described biological sample and/or relevant liquid, to control the operation of described microfluidic device.Relevant liquid was separated by and is split into drop group and deposits by the time interval of unallocated liquid, thereby made sample move into site predetermined in microfluidic device to optimize determination test with the number of times of selecting.

Accompanying drawing explanation

Fig. 1 has represented the microfluidic device of embodiment 1.

Embodiment

Definition

The following term definition using is herein as follows:

" spectrum picture " refers to that the region that comprises reagent is to being deposited on the detailed view of the optic response of the biological sample on this region that comprises reagent, for example utilize the variation of color, reflectance, penetrability or absorbance or other side, as Raman spectrum, fluorescence, chemiluminescence, phosphorescence or electrochemical impedance collection of illustrative plates, described detailed view makes it possible to the subunit in the whole region that comprises reagent to check.Described image can be multidimensional, has wherein added the site (being x-y) of optic response.

" water wettability " surface is on this surface and is set to those surfaces between water droplet thereon with the contact angle that is less than 90 °.

" hydrophobicity " surface is on this surface and is set to those surfaces between water droplet thereon with 90 ° or larger contact angle.

The interaction of liquid and porous substrate

The improvement that the invention provides the reaction to occurring in porous substrate (" pad ") is controlled, and described porous substrate comprises dry reagent and is positioned at microfluidic device.Described reaction is caused by the interaction between sample liquids and the pad that comprises reagent.

When the fluid sample of the analyte that contains unknown quantity contacts the pad that comprises reagent, described liquid must dissolve described reagent so that can occur with reacting of analyte, it produces detectable result, and for example unique optical signalling is as color, and this can record by spectroscopy means.The impact that the speed that reaction occurs and the detectable degree of result are subject to many factors.These factors comprise the relative quantity of reagent and liquid in the region that accessibility, its solubleness in liquid and the liquid of reagent places.If want to obtain unanimously and accurately result, evenly apply liquid to porous pad very important.Equally, the character of pad, for example its hydrophobicity/water wettability, its factor of porosity and capillary degree, with and thickness be also the factor that determines test result.The character of pad not only affects the volume that is absorbed liquid, also affects the dissolving and the surface interaction that are dried to the reagent on described pad.They also affect the direction of liquid flow and in the ability of specific site place fixating reagent.For example, pad is for example used together with film with film conventionally, described film make hydraulic fluid side to and non-perpendicular to flowing.Therefore the number of times of fluid communication can be realized at the conversion zone limiting.When conversion zone comprises fixing bioaffinity molecule for example when antibody and nucleic acid, the number of times of fluid communication can improve capture rate.In practice, when those skilled in the art find to design practical mensuration system, the physical property of advance capital for body, reagent and sample liquids all must be considered.

Compare to the pad that comprises reagent to Direct precipitation sample (and relevant liquid), at sample described in microfluidic device, will be added to entrance, then by hole and the capillary channel at interval, transfer in the chamber that contains the pad that comprises reagent.Conventionally sample mixes mutually or is diluted with other liquid, and described other liquid is liquid reagent for example.Described sample can be before liquid reagent, simultaneously or add in microfluidic device afterwards.Can use single or multiple entrances.Although sample, liquid reagent and potpourri can differently flow, it is very important that evenly distributing liquid remains.

In the present invention, with the little increment of accurate pattern specific times (times) ground, to target area, regularly applying sample liquids and/or other relevant liquid provides interactional improvement between liquid and the pad that comprises reagent has been controlled, thereby the accuracy of raising and the homogeneity of result are provided.

Deposit liquid sample

In much mensuration, reagent is positioned in porous substrate or " pad ", and the base material of described bar shaped is immersed in tested biofluid.Although this mensuration is very practical, it can not have necessary accuracy or repeatability as desired.The sample drop (being 1-7 μ L to 20.4 μ L) that proof deposition is large is before good not as test-strips is immersed to effect liquid.Yet droplet (being 50pL to 1 μ L) has good result in biological test array.

Two class distributing nozzles had been described before.The first has adopted single-nozzle to distribute a series of single drops to the base material that comprises reagent.Described nozzle or base material provide uniform covering by mobile with the region desirable.Equations of The Second Kind nozzle has adopted the plate that is drilled with a succession of hole, so once can distribute the drop of a plurality of series.In two types, minimum drop size has been considered to about 50pL, and this is relevant with the bore dia of about 45-50 μ m.Described nozzle can be controlled by the pressure from various sources.Adopting piezoelectric actuator is a kind of method for optimizing that distributes described droplet.

Microfluidic device

In the U.S. Patent application 10608671 of announcing as U.S.2004/0265172A1, entering and moving process that biological sample contacts with the reagent that is included in microfluidic device has been discussed.This device has the cumulative volume of about 0.1 to 200 μ L conventionally, yet, according to its purposes, also can there is greater or lesser volume.In general, microfluidic device can move first liquid and control by the second liquid by scheduled volume, and described movement arrives capillary barrier or introduces the second liquid of aequum.Method of the present invention provides in microfluidic device liquid more accurately to move.

In published application U.S.2006/0263902A1, described the droplet Direct precipitation of biological sample to the advantage on the porous substrate that comprises reagent.The method is not suitable for microfluidic device, and described microfluidic device utilizes capillary force to come moving liquid sample to contact with the reagent in microfluidic device.

The experience of relevant microfluidic device shows, test result is subject to the impact with the biological sample amount of reagent reacting.This will expect, because the explanation to result, for example, from colour developing, determines the amount of analyte, is based on being used for the amount of the analyte in the biological sample of calibration measurement instrument.Although the amount of biological sample can utilize hole or the kapillary with known volume to define, have been found that the variable in these midget plant groups has been enough to cause unacceptable changeability in result.Volume difference is a factor, but particularly important factor relates to the character that is called as " capillary barrier (capillarystop) ".These capillary barriers are placed in device, have wherein utilized the variation of capillary channel size to stop liquid under capillary force, to continue to flow.In practice, biological sample and liquid such as damping fluid, wash liquid (wash liquid), additive reagent etc. can add with the amount that causes capillary barrier to be overcome, thereby liquid is moved forward in described device.For example, if biological sample is introduced into microfluidic device and moves to the entrance of the chamber that comprises reagent by capillary force, it pauses at capillary barrier place, then must overcome this barrier to make described sample move into chamber.This can by introduce liquid for example wash liquid in entrance, realize, it causes capillary barrier to be overcome and biological sample moves into the chamber that comprises reagent.The variation that it is found that capillary action force intensity and capillary barrier has adverse influence to the character of microfluidic device.Although there is this changeability, described device still provides Useful Information, but still need seek to improve.

The form with droplet of having been found that applies biological sample and other liquid and moves through aspect this device and have significant advantage at control liquid to the entrance of microfluidic device.Capillary channel in microfluidic device contains very little liquid volume, for example 5nL/mm.Therefore, only use the liquid of little increment just can overcome described capillary barrier.Need the accurate drop that distributes to cause capillary barrier, make the beginning of described distribution and stop caning be controlled in nano-seconds.This being distributed in accurately in the time being determined by reagent reacting realized, and this time is measured by spectroscopy means.It is found that the pattern of dispense event is to keeping Uniform Flow very important.Especially, have been found that with known amount dispense liquid interval not carry out the time of liquid distribution, make to control the order that liquid moves in previous not obtainable mode.This is proven in following examples, and biological sample in described embodiment (whole blood) is added into microfluidic device, is then cracking (lysis) and wash solution.

Embodiment 1

Used following abbreviation: PBS-phosphate buffer BSA-bovine serum albumin(BSA) FITC-fluorescein isothiocynate

On cellulose nitrate base material (5.0 μ m hole), carry out HbA _1Cimmunoassays, are placed with two capture zones that 4mm is wide on described base material.The first band includes HbA _1Cagglutinator (analyte HbA _1Canalogies; 1mg/mL is in PBS, pH7.4).The second band comprises monoclonal anti-FITC mAb, and (3mg/mL, in 0.05 borate, pH8.5).

For the preparation of in conjunction with HbA _1Cthe conjugate of analyte, it comprises to be connected to uses FITC and HbA _1Cblue latex particles on the BSA of antibody labeling.Prepare two kinds of concentration for high (8-15%HbA _1C) and low (3-8%HbA _1C) in concentration determination.The material of described BSA mark is connected to blue latex particles (300nm, the COOH/g of 67 μ eq.) upper, every milligram of latex loads the anti-HbA of 30 μ g BSA-FITC- _1C.The PBS wash solution that contains 01%BSA is for described high concentration range, and 1: 10 dilution of anti-FITC antibody latex conjugate is for described low strength range.Described anti-FITC antibody is with every 1mg blue latex particles 10 μ g antibody preparations.Described conjugate is diluted and is dried in all-glass paper with casein blocking-up damping fluid.Dilution proportion to conjugate described in high concentration range with 1: 4, the dilution proportion to low strength range with 1: 400.Work as HbA _1Cwhile being present in biological sample (being blood in this example), it is in connection with to described conjugate.Then the conjugate of combination will be combined with described aggegation band, but can pass through the second band, and at the second band place, it can be combined with anti-FITC antibody.Excessive conjugate will be by described the first band combination, because it can be attached to the HbA in described conjugate _1Con antibody.The relative quantity that is present in two FITC on capture zone by measurement, can determine HbA in sample _1Camount.

The described cellulose nitrate bar that contains two capture zones is placed in microfluidic device, as shown in fig. 1.This device has four chambers, connects, and have the cumulative volume of about 20 μ L by capillary channel.Described the first chamber is the entrance of described device.Environment is open towards periphery for it.Chamber 2 comprises and is positioned on all-glass paper and the conjugate being supported by small post.Nitrocellulose capture strip is in chamber 3, and its inlet port (entrance) contains small post array with distribution liquid.Chamber 4 comprises for remove the porous pad of excess liq from chamber 3.

During use, sample (whole blood) is added in chamber 1, it is used for determining the volume of described sample.Described sample flows through kapillary and stops at the inlet port place of chamber 2.Add lysate (Cellytic-M, Sigma Aldrich, St.Louis, MO) to force sample to enter chamber 2, here it contacts described conjugate.After described conjugate particles and described example reaction, to chamber 1, add wash liquid to force described sample and conjugate by the barrier at chamber 3 inlet port places, make the sample of dilution by the capture zone on described.By the FITC in described capture zone, develop the color and the CCD camera that is used as fluorescence detector reads, then by suitable software, compare with correction data.Additional liquid is fed to chamber 1 and with mobile residual sample, enters chamber 4, contain absorption pad here.

With this microfluidic device, test, wherein used three kinds of methods to add liquid in chamber 1.There is about 0.3 to 2mm opening and according to it, fill length and can distribute the conventional capillary pipet of about 0.3-100 μ L drop to be used for sample and other liquid to be placed in entrance.There is micro-dispensing head of about 50 μ m openings to distribute described sample and liquid without the mode of pausing continuously.Identical micro-dispensing head is also for accurately moving liquid is to overcome capillary barrier discontinuously and periodically, and in the time interval of described interruption, no liquid is assigned with.Have been found that (attimes) droplet is best suited for the reaction that provides clear good results every now and then, as shown in the table.

Distribution method	% crosses filling	% lack of fill	The inhomogeneous color of %	Response timing
					Large transfer pipet	32％	23％	18％	10-20 second
Differential is joined (continuously)	16％	9％	17％	～3-6 second
					Regularly the differential of group is joined	0.1％	0.3％	1.2％	～> 0.01 second

In upper table, " % crosses and fills or % lack of fill " refers to a series of tests, wherein tested the microfluidic device of Fig. 1 and wherein found and added than the required more or few liquid of reaction." the inhomogeneous color of % " refers to the colour developing in chamber 3, and it has been indicated the amount of the conjugate of catching and has allowed HbA in calculation sample _1Camount." response timing " refers to that liquid starts to flow to from chamber 2 minimum time that chamber 3 experiences in described microfluidic device.These tests were implemented conventionally in 1 to 10 minute, comprised incubation and colour developing.The error of incubation and developing time can cause the error of response, because have than the more or less reagent of expection, reaction has occurred.

Embodiment 2

The micro-dispensing head using in previous embodiment can be with the drop of the about 100pL of rate-allocation of 85/microsecond.Except by the distribution time period that interval separated of unallocated liquid, can also control the volume distributing in each time period, i.e. number of drops in each time period.This ability makes Quality control and dilution more accurately move through described microfluidic device.At above-mentioned HbA _1Cin mensuration, it is very important providing incubation for sample and conjugate of appropriate time and sample/conjugate to complete before the described test-strips of washing and reacting.This need to monitor sample process and control the time of adding dilution.Sample and sample/conjugate move for optimizing mensuration very important with specific speed.This becomes possibility when the position of monitoring sample and sample/conjugate is also controlled the interpolation of dilution accordingly continuously.

In this embodiment, control described differential and be equipped with the group that provides 85 every millisecond, between interval 0.1 second.When joining while comparing with transfer pipet and continuous differential, obtained following result

Distribution method	Timing precision	The minimum volume of adding	Volume tolerance
				Large transfer pipet	～1 second	1.7μL	0％
Differential is joined (continuously)	～0.5 millisecond	5.0nL	80％
				The differential of reinforcement group is joined	～0.01 millisecond	100pL	99.6％

In upper table, " timing precision " refers to and implements the required minimum time section of described distribution method." minimum volume of interpolation " refers to the degree that every kind of distribution method can be controlled." volume tolerance " relates to the variable of volume, by it, can expect the optimum operation of described microfluidic device.In the present embodiment, the kapillary between chamber has the volume of about 50nL, and it is the minimum volume that can add before the capillary barrier at described capillary end place is initiated.When the minimum volume of distributing is greater than 50nL, for large transfer pipet, volume tolerance is zero.Even when using kapillary as transfer pipet, the volume of 0.3 μ L (300nL) also can have zero volume tolerance.

Use has the differential of intensive drop group joins, and minimum group is one.In this embodiment, drop take that the speed of 85 droplets/millisecond is distributed and the volume of every is 100pL.Described volume is approximately 0.1 μ L/ millisecond (8.5nL/ millisecond).In general this is good opereating specification.It provides the transmitting (fire) on time reliably of high volume tolerance and described microfluidic device 99.996%.Because described device is monitored by spectrum picture, just can proofread and correct the error transmitting in described microfluid kapillary volume or change by extra drop group.Common opereating specification is 30 to 150 droplets/millisecond, and described droplet size is at about 30pL to 1000nL.

When adopting continuous differential timing, described divider can deceleration of electrons, but conventionally can distribute a more than drop.In this embodiment, " minimum volume of interpolation " is 50 0.100nL or 5nL.This means that volume tolerance is not high or be time (4/5ths) of 80% for this device.Because microfluidic device can be worked together with only holding the kapillary of 5nL, therefore this tolerance is than can acceptance the observation of joining with reinforcement group differential less.

Claims (19)

1. in microfluidic device, measure the method for the amount of analyte in biofluid, described microfluidic device has at least one sample inlet, at least one blow vent, and at least one chamber that comprises reagent, and described method comprises:

(a) sample of described biofluid is assigned in described at least one sample inlet of described microfluidic device, described sample moves through by capillary force the capillary channel being communicated with described at least one sample inlet and arrives capillary barrier;

(b) liquid that a part is different to the sample described in (a) is assigned at least one entrance described in (a), described liquid is enough to force described sample by described capillary barrier, with diameter, the form in the drop group of 0.05 to 1mm scope is assigned with described liquid, described drop group was separated by the time interval of unallocated drop, and described liquid adds in predetermined time after introducing described sample;

Wherein the described drop group of the different liquids described in (b) drips to 150,000 speed per second by micro-distributing nozzle with 30,000 and is assigned with.

2. the process of claim 1 wherein that the different liquids described in (b) is introduced into the amount that surpasses the position of described capillary barrier in described microfluidic device to be enough to making the to own sample displacement described in (a).

3. the method for claim 2, the wherein said reagent being distributed in described at least one chamber that comprises reagent by the contact of the sample of displacement and substitute the air existing in described at least one chamber.

4. the method for claim 3, what wherein said sample and described reagent reacting the amount to described analyte in described sample of producing were relevant can testing result.

5. the method for claim 2, wherein said by the sample of displacement contact correctives or support agent so that described sample is ready for use on contacting of follow-up and reagent.

6. the process of claim 1 wherein that described microfluidic device has the cumulative volume of 0.1 to 200 μ L.

7. the process of claim 1 wherein that the smallest group of drop has the volume of about 100pL.

8. the method for claim 7, the timing precision of wherein said distribution is about 0.01 millisecond.

9. in microfluidic device, measure the method for the amount of analyte in biofluid, described microfluidic device has at least one sample inlet, at least one blow vent, and at least one chamber that comprises reagent, described mensuration comprises the sample of described biofluid is assigned in described at least one entrance, and the liquid that is different from described sample by distribution makes described sample displacement in described at least one entrance

It is characterized in that described method comprises the described different liquid of form distribution in the drop group of 0.05 to 1mm scope with diameter, described drop group was separated by the time interval of unallocated drop;

The described drop group of wherein said different liquids drips to 150,000 rate-allocation per second by micro-distributing nozzle with 30,000.

10. the method for claim 9, the sample of wherein said biofluid moves to the capillary barrier place in the capillary channel being communicated with described at least one sample inlet by capillary force, and described different liquid is to be enough to forcing described sample to distribute by the amount of described capillary barrier.

The method of 11. claims 10, the sample of wherein said biofluid is forced through described capillary barrier and enters described at least one chamber that comprises reagent.

The method of 12. claims 10, what wherein said sample and described reagent reacting the amount to described analyte in described sample of producing were relevant can testing result.

The method of 13. claims 10, wherein said sample contact correctives or support agent are so that described sample is ready for use on contacting of follow-up and reagent.

The method of 14. claims 9, wherein said microfluidic device has the cumulative volume of 0.1 to 200 μ L.

The method of 15. claims 9, wherein minimum drop group has the volume of about 100pL.

The method of 16. claims 9, the timing precision of wherein said distribution is about 0.01 millisecond.

The method of 17. claims 10, the volume of the different liquids being wherein assigned with is about 5nL.

The method of 18. operation microfluidic devices, described microfluidic device has at least one entrance, at least one blow vent, and at least one chamber, described method comprises:

(a) with diameter, in the form of the drop group of 0.05 to 1mm scope, distribute the first liquid of scheduled volume in described at least one entrance;

(b) second liquid that is enough to force described first liquid to leave the scheduled volume of described at least one entrance is assigned in described at least one entrance, with diameter, the form in the drop group of 0.05 to 1mm scope is assigned with described second liquid, the drop group of described second liquid was separated by the time interval of unallocated drop, the predetermined time interpolation of described second liquid after introducing described first liquid, the drop group of wherein said second liquid drips to 150,000 rate-allocation per second by micro-distributing nozzle with 30,000.

The method of 19. claims 18, wherein said microfluidic device is included in the capillary channel being communicated with between described at least one entrance and described at least one chamber, and described first liquid moves at the capillary barrier place that leads to the inlet port of described at least one chamber from described entrance by capillary force.